Statistical modeling of single-cell epitranscriptomics enabled trajectory and regulatory inference of RNA methylation

Haozhe Wang; Yue Wang; Jingxian Zhou; Bowen Song; Gang Tu; Anh Nguyen; Jionglong Su; Frans Coenen; Zhi Wei; Daniel J. Rigden; Jia Meng

doi:10.1016/j.xgen.2024.100702

Statistical modeling of single-cell epitranscriptomics enabled trajectory and regulatory inference of RNA methylation

Haozhe Wang, Yue Wang^*, Jingxian Zhou, Bowen Song, Gang Tu, Anh Nguyen, Jionglong Su, Frans Coenen, Zhi Wei, Daniel J. Rigden, Jia Meng^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

As a fundamental mechanism for gene expression regulation, post-transcriptional RNA methylation plays versatile roles in various biological processes and disease mechanisms. Recent advances in single-cell technology have enabled simultaneous profiling of transcriptome-wide RNA methylation in thousands of cells, holding the promise to provide deeper insights into the dynamics, functions, and regulation of RNA methylation. However, it remains a major challenge to determine how to best analyze single-cell epitranscriptomics data. In this study, we developed SigRM, a computational framework for effectively mining single-cell epitranscriptomics datasets with a large cell number, such as those produced by the scDART-seq technique from the SMART-seq2 platform. SigRM not only outperforms state-of-the-art models in RNA methylation site detection on both simulated and real datasets but also provides rigorous quantification metrics of RNA methylation levels. This facilitates various downstream analyses, including trajectory inference and regulatory network reconstruction concerning the dynamics of RNA methylation.

Original language	English
Article number	100702
Journal	Cell Genomics
Volume	5
Issue number	1
DOIs	https://doi.org/10.1016/j.xgen.2024.100702
Publication status	Published - 8 Jan 2025

Keywords

cell cycle
epitranscriptome
gene regulatory network
mA
RNA methylation
scDART-seq
single cell
statistical modeling
trajectory inference

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title = "Statistical modeling of single-cell epitranscriptomics enabled trajectory and regulatory inference of RNA methylation",

abstract = "As a fundamental mechanism for gene expression regulation, post-transcriptional RNA methylation plays versatile roles in various biological processes and disease mechanisms. Recent advances in single-cell technology have enabled simultaneous profiling of transcriptome-wide RNA methylation in thousands of cells, holding the promise to provide deeper insights into the dynamics, functions, and regulation of RNA methylation. However, it remains a major challenge to determine how to best analyze single-cell epitranscriptomics data. In this study, we developed SigRM, a computational framework for effectively mining single-cell epitranscriptomics datasets with a large cell number, such as those produced by the scDART-seq technique from the SMART-seq2 platform. SigRM not only outperforms state-of-the-art models in RNA methylation site detection on both simulated and real datasets but also provides rigorous quantification metrics of RNA methylation levels. This facilitates various downstream analyses, including trajectory inference and regulatory network reconstruction concerning the dynamics of RNA methylation.",

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author = "Haozhe Wang and Yue Wang and Jingxian Zhou and Bowen Song and Gang Tu and Anh Nguyen and Jionglong Su and Frans Coenen and Zhi Wei and Rigden, {Daniel J.} and Jia Meng",

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year = "2025",

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doi = "10.1016/j.xgen.2024.100702",

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AU - Wang, Haozhe

AU - Wang, Yue

AU - Zhou, Jingxian

AU - Song, Bowen

AU - Tu, Gang

AU - Nguyen, Anh

AU - Su, Jionglong

AU - Coenen, Frans

AU - Wei, Zhi

AU - Rigden, Daniel J.

AU - Meng, Jia

PY - 2025/1/8

Y1 - 2025/1/8

N2 - As a fundamental mechanism for gene expression regulation, post-transcriptional RNA methylation plays versatile roles in various biological processes and disease mechanisms. Recent advances in single-cell technology have enabled simultaneous profiling of transcriptome-wide RNA methylation in thousands of cells, holding the promise to provide deeper insights into the dynamics, functions, and regulation of RNA methylation. However, it remains a major challenge to determine how to best analyze single-cell epitranscriptomics data. In this study, we developed SigRM, a computational framework for effectively mining single-cell epitranscriptomics datasets with a large cell number, such as those produced by the scDART-seq technique from the SMART-seq2 platform. SigRM not only outperforms state-of-the-art models in RNA methylation site detection on both simulated and real datasets but also provides rigorous quantification metrics of RNA methylation levels. This facilitates various downstream analyses, including trajectory inference and regulatory network reconstruction concerning the dynamics of RNA methylation.

AB - As a fundamental mechanism for gene expression regulation, post-transcriptional RNA methylation plays versatile roles in various biological processes and disease mechanisms. Recent advances in single-cell technology have enabled simultaneous profiling of transcriptome-wide RNA methylation in thousands of cells, holding the promise to provide deeper insights into the dynamics, functions, and regulation of RNA methylation. However, it remains a major challenge to determine how to best analyze single-cell epitranscriptomics data. In this study, we developed SigRM, a computational framework for effectively mining single-cell epitranscriptomics datasets with a large cell number, such as those produced by the scDART-seq technique from the SMART-seq2 platform. SigRM not only outperforms state-of-the-art models in RNA methylation site detection on both simulated and real datasets but also provides rigorous quantification metrics of RNA methylation levels. This facilitates various downstream analyses, including trajectory inference and regulatory network reconstruction concerning the dynamics of RNA methylation.

KW - cell cycle

KW - epitranscriptome

KW - gene regulatory network

KW - mA

KW - RNA methylation

KW - scDART-seq

KW - single cell

KW - statistical modeling

KW - trajectory inference

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DO - 10.1016/j.xgen.2024.100702

M3 - Article

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SN - 2666-979X

VL - 5

JO - Cell Genomics

JF - Cell Genomics

IS - 1

M1 - 100702

ER -

Statistical modeling of single-cell epitranscriptomics enabled trajectory and regulatory inference of RNA methylation

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Keywords

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